Rational Numbers

Can be expressed as the quotient of two integers (ie a fraction) with a denominator that is not zero. Many people are surprised to know that a repeating decimal is a rational number. The venn diagram below shows examples of all the different types of rational, irrational nubmers including integers, whole numbers, repeating decimals and more.

Set of Real Numbers Venn Diagram

Examples of Rational Numbers

5

You can express 5 as $$ \frac{5}{1} $$ which is the quotient of the integer 5 and 1

2

You can express 2 as $$ \frac{2}{1} $$ which is the quotient of the integer 2 and 1

$$ \sqrt{9} $$

is rational because you can simplify the square root to 3 which is the quotient of the integer 3 and 1

More Examples of Irrational Numbers

$$ \frac{ \sqrt{2}}{3} $$

Although this number can be expressed as a fraction, we need more than that, for the number to be rational . The fraction's numerator and denominator must both be integers, and $$\sqrt{2} $$ cannot be expressed as an integer.

$$.2020020002 ...$$

This non terminating decimal does not repeat . So, just like $$ \pi $$, it constantly changes and can not be represented as a quotient of two integers

Practice Problems

Problem 1

Is the number $$ -12 $$ rational or irrational?

Rational because it can be written as $$ -\frac{12}{1}$$, a quotient of two integers.

Problem 2

Is the number $$ \sqrt{ 25} $$ rational or irrational?

Rational, because you can simplify $$ \sqrt{25} $$ to the integer $$ 5 $$ which of course can be written as $$ \frac{5}{1} $$, a quotient of two integers.

Problem 3

Is the number $$ 0.09009000900009... $$ rational or irrational?

This is irrational, the ellipses mark $$ \color{red}{...} $$ at the end of the number $$ \boxed{ 0.09009000900009 \color{red}{...}} $$, means that the pattern of increasing the number of zeroes continues to increase and that this number never terminates and never repeats.

Problem 4

Is the number $$ 0.\overline{201} $$ rational or irrational?

This is rational. All repeating decimals are rational (see bottom of page for a proof.)

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Problem 5

Is the number $$ \frac{ \sqrt{3}}{4} $$ rational or irrational?

This is irrational. You cannot simplify $$ \sqrt{3} $$ which means that we can not express this number as a quotient of two integers.

Problem 6

Is the number $$ \frac{ \sqrt{9}}{25} $$ rational or irrational?

Unlike the last problem , this is rational. You can simplify $$ \sqrt{9} \text{ and also } \sqrt{25} $$. If you simplify these square roots, then you end up with $$ \frac{3}{5} $$, which satisfies our definition of a rational number (ie it can be expressed as a quotient of two integers)

Problem 7

Is the number $$ \frac{ \pi}{\pi} $$ rational or irrational?

This is rational because you can simplify the fraction to be the quotient of two integers (both being the number 1)